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Query: UMLS:C0002878 (
hemolytic anemia
)
7,530
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Rhesus D (RhD) typing is performed by agglutination methods; however, in clinical situations where these techniques cannot be performed, RhD DNA typing is an alternative approach. The Rh antigens are encoded by the RHD and
RHCE
genes. In RhD-negative individuals the RHD gene is absent or grossly deleted, but variations in the arrangement of the RH locus in different populations are emerging. The aim of this study was to analyse the gross organization of the RH genes in our population using a previously described multiplex polymerase chain reaction (PCR) method with some modifications. We studied 253 DNA samples from Argentinian blood donors, 15 samples with a reduced expression of the D antigen and 1 Dc- phenotype. We evaluated the clinical utility of this method to ascertain the RhD antigen in 10 patients with warm-type autoimmune
haemolytic anaemia
(AIHA) and 14 samples of amniotic fluids. All Rh phenotypes were properly characterized and no discrepancies with serological typing were found. Analyses performed in the Dc- phenotype suggest the presence of a hybrid
RHCE
-RHD gene. DNA typing confirmed the RhD-negative type of one AIHA sample in which serological tests were inconclusive. Foetal DNA typing correctly indicated the RhD in every foetus. VNTR (variable number of tandem repeats) and STR (short tandem repeats) analysis detected maternal contamination in two amniocentesis samples and confirmed the foetal origin of 12. This multiplex PCR strategy is suitable for RhD determination in clinical situations in which serological typing cannot be accomplished with its usual ease.
...
PMID:Molecular determination of RhD phenotype by DNA typing: clinical applications. 1108 23
The Rh antigens are encoded by the RHD and
RHCE
genes. In RhD negative individuals the RHD gene is absent or grossly deleted. Routinely, Rh typing is performed by haemagglutination. However, there are some clinical situations in which serological techniques are not suitable for determining the red blood cell phenotype accurately. Most anti-D sera may not agglutinate erythrocytes possessing a reduced expression of the D antigen. In these cases, DNA-based analyses may be better than serological typing to infer the appropriate phenotype. Agglutination methods are also of limited use for determining the red blood cell phenotype of a foetus at risk of haemolytic disease of the newborn. Molecular RHD typing using amniocytes or DNA obtained from maternal plasma may obviate the need of amniocenteses during pregnancy when the foetus is RhD negative, thus providing an important tool in managing possible sensitization by foetal erythrocytes. Classical haemagglutination has limitation in patients with autoimmune
haemolytic anaemia
. Erythrocytes coated with IgG cannot be accurately typed for red blood cell antigens, particularly when directly agglutinating antibodies are not available or IgG removal by chemical treatment is insufficient. Molecular genotyping is very important for determination of the true blood group antigens of these patients. RHD genotyping with a specificity and sensitivity comparable to serologic methods is of practical importance to overcome the limitations of serology and, in addition, to improve the currently possible resolution.
...
PMID:Clinical aspects of Rh genotyping. 1207 77
Rh(null) red cells are characteristically stomato-spherocytic. This and other evidence suggest that the Rh complex represents a major attachment site between the membrane lipid bilayer and the erythroid skeleton. As an attempt to identify the linking protein(s) between the red cell skeleton and the Rh complex, we analyzed the expression of Rh, RhAG, CD47, LW, and glycophorin B proteins in red cells from patients with hereditary spherocytosis associated with complete protein 4.2 deficiency but normal band 3 (4.2(-)HS). Flow cytometric and immunoblotting analysis revealed a severe reduction of CD47 (up to 80%) and a slower mobility of RhAG on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, possibly reflecting an overglycosylation state. Unexpectedly, 4.2(-/-) mice, which are anemic, displayed a normal red cell expression of CD47 and RhAG. These results suggest that human protein 4.2, through interaction with CD47, is involved in the skeleton linkage and/or membrane translocation of the Rh complex. However, these potential role(s) of protein 4.2 might be not conserved across species. Finally, the absence or low expression of red cell CD47 in CD47(-/-) mice and in some humans carrying
RHCE
gene variants (D--, D., and R(N)), respectively, had no detectable effect on protein 4.2 and RhAG expression. Since these cells are morphologically normal with no sign of hemolysis, it is assumed that CD47 deficiency per se is not responsible for the cell shape abnormalities and for the compensated
hemolytic anemia
typical of 4.2(-) and Rh(null) red cells.
...
PMID:Evidence that the red cell skeleton protein 4.2 interacts with the Rh membrane complex member CD47. 1239 67
Initial Rh phenotyping of a man with
hemolytic anemia
, his wife, and son appeared to exclude paternity. No exclusion was found in other blood groups or in the human leukocyte antigen (HLA) system; excluding Rh, the paternity index was 98.58 percent. Samples from these three family members, and two other family members, were tested with additional Rh antisera. The results indicated that the propositus has an Rhmod phenotype with expression of c, weak e, and very weak D, E, and G antigens. To support this hypothesis, DNA analysis of the RHD and
RHCE
genes was performed on the five family members. Polymerase chain reaction (PCR) products from exons 2 and 5 were analyzed by denaturing gradient gel electrophoresis (DGGE). The DNA results corroborated the serologic findings and refuted the exclusion of paternity.
...
PMID:Rhmod phenotype: a parentage problem solved by denaturing gradient gel electorphoresis of genomic DNA. 1538 27
Rh (Rhesus) proteins (D, CcEe) are expressed in red cells (RBC) in association with other membrane proteins (RhAG, LW, CD47 and GPB). By interacting with the spectrin-based skeleton through protein 4.2 and ankyrin, the Rh complex contributes to the maintenance of the mechanical properties of the erythrocyte membrane. The RH system is one of the most immunogenic and polymorphic human blood group system. Molecular basis of most Rh phenotypes, including the Rh(null) phenotype associated with
hemolytic anemia
, have been determined. The demonstration that the RHD-positive locus is composed of the RHD and
RHCE
genes, whereas the RHD gene is deleted in most RhD-negative individuals, allowed fetal RhD genotyping by non-invasive PCR assays for antenatal diagnosis of pregnancy at risk for Rh hemolytic disease of the newborn. In mammals, the Rh protein family includes two non-erythroid members, RhBG and RhCG, mainly expressed in liver and kidney, two organs specialized in ammonia genesis and excretion. Functional analyses in heterologous systems revealed that RhAG, RhBG and RhCG can mediate ammonium (NH(3) and/or NH(4)(+)) transport across the cell membrane and might represent mammalian specific ammonium transporters. Furthermore, recent studies performed in human and murine red blood cells (RBC) indicate that RhAG facilitates CH(3)NH(2)/NH(3) movement across the membrane and represents a potential example of gas channel. The crystallographic structure of the bacterial ammonia channel AmtB and functional studies showing that AmtB conducts NH(3) into reconstituted vesicles is fully consistent with these latter studies. In RBCs, RhAG may transport NH(3) to detoxifying organs like kidney and liver and with non-erythroid tissues orthologs may contribute to regulation of the acid-base balance.
...
PMID:Rh proteins: key structural and functional components of the red cell membrane. 1596 Dec 4
The Rh system clinically is one of the important blood groups. The major Rh antigens are RhD, RhC/c, and RhE/e, which are carried by two integral membrane polypeptides consisted of 416 amino acids. These polypeptides are encoded by two closely related genes, RHD and
RHCE
. Both RH genes are composed of ten exons. It is thought that multiple recombinations, nucleotide substitutions, large nucleotide gaps (due to Alu sequence), and high level of the homology between the RHD and
RHCE
genes are the important factors in the formation and evolution of these genes. The RHD gene is deleted in most white individuals who lack the RhD antigen, while 12% of Japanese individuals have an RHD gene. Molecular analyses have elucidated the background of various Rh-related variants; D--, partial D, weak D, and Rhnull. The Rhnull phenotype is divided into the most common type by the Rhnull regulator gene and second type by the amorph gene that arose by homozygosity of a silent allele at the RH locus. The RhAG glycoprotein has been regarded as a most critical Rhnull gene of the reglurator type and a critical co-expressing factor of the Rh polypetides on red blood cells. Studies on the autoantibodies against red blood cells in aoutoimmune
hemolytic anemia
have suggested that the public epitopes of autoantigens exist on the Rh polypeptides.
...
PMID:[Molecular approaches to the Rh blood group system]. 1713 12
